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Nuclear Genome Sequence of the Plastid Nuclear genome sequence of the plastid-lacking cryptomonad Goniomonas avonlea provides insights into the evolution of secondary plastids Ugo Cenci, Shannon Sibbald, Bruce Curtis, Ryoma Kamikawa, Laura Eme, Daniel Moog, Bernard Henrissat, Eric Marechal, Malika Chabi, Christophe Djemiel, et al. To cite this version: Ugo Cenci, Shannon Sibbald, Bruce Curtis, Ryoma Kamikawa, Laura Eme, et al.. Nuclear genome sequence of the plastid-lacking cryptomonad Goniomonas avonlea provides insights into the evolution of secondary plastids. BMC Biology, BioMed Central, 2018, 16 (1), pp.137. 10.1186/s12915-018- 0593-5. hal-02046523 HAL Id: hal-02046523 https://hal.archives-ouvertes.fr/hal-02046523 Submitted on 26 May 2020 HAL is a multi-disciplinary open access L’archive ouverte pluridisciplinaire HAL, est archive for the deposit and dissemination of sci- destinée au dépôt et à la diffusion de documents entific research documents, whether they are pub- scientifiques de niveau recherche, publiés ou non, lished or not. The documents may come from émanant des établissements d’enseignement et de teaching and research institutions in France or recherche français ou étrangers, des laboratoires abroad, or from public or private research centers. publics ou privés. Distributed under a Creative Commons Attribution| 4.0 International License Cenci et al. BMC Biology (2018) 16:137 https://doi.org/10.1186/s12915-018-0593-5 RESEARCH ARTICLE Open Access Nuclear genome sequence of the plastid- lacking cryptomonad Goniomonas avonlea provides insights into the evolution of secondary plastids Ugo Cenci1,2†, Shannon J. Sibbald1,2†, Bruce A. Curtis1,2, Ryoma Kamikawa3, Laura Eme1,2,11, Daniel Moog1,2,12, Bernard Henrissat4,5,6, Eric Maréchal7, Malika Chabi8, Christophe Djemiel8, Andrew J. Roger1,2,9, Eunsoo Kim10 and John M. Archibald1,2,9* Abstract Background: The evolution of photosynthesis has been a major driver in eukaryotic diversification. Eukaryotes have acquired plastids (chloroplasts) either directly via the engulfment and integration of a photosynthetic cyanobacterium (primary endosymbiosis) or indirectly by engulfing a photosynthetic eukaryote (secondary or tertiary endosymbiosis). The timing and frequency of secondary endosymbiosis during eukaryotic evolution is currently unclear but may be resolved in part by studying cryptomonads, a group of single-celled eukaryotes comprised of both photosynthetic and non-photosynthetic species. While cryptomonads such as Guillardia theta harbor a red algal-derived plastid of secondary endosymbiotic origin, members of the sister group Goniomonadea lack plastids. Here, we present the genome of Goniomonas avonlea—the first for any goniomonad—to address whether Goniomonadea are ancestrally non-photosynthetic or whether they lost a plastid secondarily. Results: We sequenced the nuclear and mitochondrial genomes of Goniomonas avonlea and carried out a comparative analysis of Go. avonlea, Gu. theta, and other cryptomonads. The Go. avonlea genome assembly is ~ 92 Mbp in size, with 33,470 predicted protein-coding genes. Interestingly, some metabolic pathways (e.g., fatty acid biosynthesis) predicted to occur in the plastid and periplastidal compartment of Gu. theta appear to operate in the cytoplasm of Go. avonlea, suggesting that metabolic redundancies were generated during the course of secondary plastid integration. Other cytosolic pathways found in Go. avonlea are not found in Gu. theta, suggesting secondary loss in Gu. theta and other plastid-bearing cryptomonads. Phylogenetic analyses revealed no evidence for algal endosymbiont-derived genes in the Go. avonlea genome. Phylogenomic analyses point to a specific relationship between Cryptista (to which cryptomonads belong) and Archaeplastida. Conclusion: We found no convincing genomic or phylogenomic evidence that Go. avonlea evolved from a secondary red algal plastid-bearing ancestor, consistent with goniomonads being ancestrally non-photosynthetic eukaryotes. The Go. avonlea genome sheds light on the physiology of heterotrophic cryptomonads and serves as an important reference point for studying the metabolic “rewiring” that took place during secondary plastid integration in the ancestor of modern-day Cryptophyceae. Keywords: Cryptomonads, Cryptophytes, Secondary endosymbiosis, Phylogenomics, Genome evolution * Correspondence: [email protected] †Ugo Cenci and Shannon J. Sibbald contributed equally to this work. 1Department of Biochemistry and Molecular Biology, Dalhousie University, Halifax, Nova Scotia B3H 4R2, Canada 2Centre for Comparative Genomics and Evolutionary Bioinformatics, Dalhousie University, Halifax, Nova Scotia, Canada Full list of author information is available at the end of the article © The Author(s). 2018 Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated. Cenci et al. BMC Biology (2018) 16:137 Page 2 of 23 Background pathways operating in different subcellular compart- The acquisition of photosynthesis in eukaryotes can be ments can become partially or completely redundant. traced back to a primary endosymbiosis in which a This allows the organism to tinker with the regulation of eukaryotic host engulfed and assimilated a photosynthetic pathways that may be adapted to a particular cellular cyanobacterium, which ultimately became the plastid compartment and/or set of metabolites. Endosymbiosis (chloroplast) [1, 2]. Canonical “primary” plastids are sur- can also give rise to mosaic metabolic pathways com- rounded by two membranes and are generally thought to prised of enzymes with different evolutionary origins have evolved on a single occasion in the common ancestor [18, 21]. Proteins may be derived from the host, from of Archaeplastida, a tripartite eukaryotic “supergroup” the endosymbiont (both primary and secondary), or as a comprised of Viridiplantae (also known as Chloroplastida), result of lateral gene transfer (LGT) from different pro- Rhodophyta (Rhodophyceae), and Glaucophyta [3–5]. karyotic and eukaryotic organisms. Understanding how Eukaryotes have also acquired photosynthesis indirectly cells adapt from living in a solitary state to having an- on multiple occasions via “secondary” (i.e., other organism within it is fundamental to understand- eukaryote-eukaryote) endosymbiosis. Indeed, secondary ing the evolution of plastid-bearing organisms. (and in some cases tertiary) endosymbiosis is thought to We have sequenced the nuclear genome and transcrip- have given rise to plastids scattered amongst the strame- tome of the plastid-lacking goniomonad Go. avonlea nopiles, alveolates, rhizarians, euglenozoans, haptophytes, CCMP3327 [7] with the goal of shedding light on its and cryptomonads [6]. The latter lineage is divided into physiology and, more generally, the metabolic trans- two clades, the plastid-bearing, mostly photosynthetic formation that accompanied the transition from hetero- Cryptophyceae and the heterotrophic Goniomonadea. The trophy to phototrophy in its plastid-bearing sister taxa. evolutionary distinctness of these two clades makes for an Using comparative genomics and phylogenomics, we interesting case study with which to understand the transi- found little evidence for a photosynthetic ancestry in Go. tion from a plastid-lacking eukaryote to a photosynthetic, avonlea and show that the acquisition of a plastid in an secondary plastid-bearing organism. ancestor of present-day Cryptophyceae resulted in exten- Guillardia theta and the recently described Goniomo- sive reshuffling of metabolic pathways. Annotation of nas avonlea [7] are representatives of plastid-bearing carbohydrate-active enzymes (CAZymes) [22] including and plastid-lacking cryptomonads [5, 8], respectively. glycosyltransferases (GTs), glycoside hydrolases (GHs), Together with several paraphyletic plastid-lacking line- polysaccharide lyases (PLs), and carbohydrate esterases ages, including katablepharids and Palpitomonas, crypto- (CEs) allows us to make several predictions about the monads constitute a clade known as Cryptista [9, 10]. lifestyle of Go. avonlea and other goniomonads, includ- The position of Cryptista on the eukaryotic tree of life is ing the possibility that they feed on multiple organisms, a point of contention. Some phylogenomic studies have including eukaryotic algae. placed it sister to Haptophyta (e.g., [11]), with the Cryptista-Haptophyta clade itself branching either next Methods to the SAR supergroup (Stramenopiles, Alveolata, Cell culture, nucleic acid preparation, and genome Rhizaria; e.g., [12]) or the Archaeplastida (e.g., [13]). sequencing Other studies have suggested that Cryptista and Hapto- Goniomonas avonlea CCMP3327 was grown in ESM phyta are not specifically related, with the former medium [23] supplemented with ATCC’s 1525 Seawater branching within the Archaeplastida [14]. Our knowledge 802 medium. One day prior to harvesting, a dose of of Cryptista and their evolutionary history has suffered Penicillin-Streptomycin-Neomycin antibiotic mixture from a paucity of genomic data [15]. Only one
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